English

Coarsening dynamics in one dimension: The phase diffusion equation and its numerical implementation

Pattern Formation and Solitons 2013-06-11 v2 Statistical Mechanics

Abstract

Many nonlinear partial differential equations (PDEs) display a coarsening dynamics, i.e., an emerging pattern whose typical length scale LL increases with time. The so-called coarsening exponent nn characterizes the time dependence of the scale of the pattern, L(t)tnL(t)\approx t^n, and coarsening dynamics can be described by a diffusion equation for the phase of the pattern. By means of a multiscale analysis we are able to find the analytical expression of such diffusion equations. Here, we propose a recipe to implement numerically the determination of D(λ)D(\lambda), the phase diffusion coefficient, as a function of the wavelength λ\lambda of the base steady state u0(x)u_0(x). DD carries all information about coarsening dynamics and, through the relation D(L)L2/t|D(L)| \simeq L^2 /t, it allows us to determine the coarsening exponent. The main conceptual message is that the coarsening exponent is determined without solving a time-dependent equation, but only by inspecting the periodic steady-state solutions. This provides a much faster strategy than a forward time-dependent calculation. We discuss our method for several different PDEs, both conserved and not conserved.

Keywords

Cite

@article{arxiv.1210.1713,
  title  = {Coarsening dynamics in one dimension: The phase diffusion equation and its numerical implementation},
  author = {Matteo Nicoli and Chaouqi Misbah and Paolo Politi},
  journal= {arXiv preprint arXiv:1210.1713},
  year   = {2013}
}
R2 v1 2026-06-21T22:16:51.689Z